Capacitor

ABSTRACT

Embodiments of the present invention include forming a thin, conformal, high-integrity dielectric coating between conductive layers in a via-in-via structure in an organic substrate, using an electrocoating process to reduce loop inductance between the conductive layers. The dielectric coating is formed using a high dielectric constant material such as an organic polymer or an organic polymer mixture. Embodiments of the present invention also include forming a thin, dielectric coating between conductive layers on a substantially planar substrate material and providing an embedded capacitor to reduce loop inductance.

This application is a divisional of U.S. patent application Ser. No.09/733,484, filed Dec. 8, 2000, now issued as U.S. Pat. No. 6,605,551,which is incorporated herein by reference in its entirety.

TECHNICAL FIELD

Embodiments of the present invention relate generally to a multilayeredorganic substrate material used as a support substrate for electroniccomponents and, more particularly, to forming a dielectric layer on themultilayered organic substrate material.

BACKGROUND

Electrical circuits, which may include electronic components, such asintegrated circuits(ICs), resistors, capacitors, and inductors, areoften supported by organic substrates. The organic substrates may alsosupport conductive traces for conveying electric current to theterminals of the electronic components. Multilayer substrates includealternating layers of conductive and organic materials. The conductivelayers comprise conductive traces interconnecting the electroniccomponents. The conductive layers may be electrically interconnected bymeans of conductive vertical interconnects, such as vias that passthrough adjacent organic layers of the multilayer structure or byelectrically conductive vias such as plated through holes that passthrough the entire substrate and are electrically continuous withselected conductive layers. The organic layers often serve as dielectriclayers on the multilayered substrates that support electroniccomponents.

In some power delivery applications, it may be desirable to have lowloop inductance between the conductive traces. For example, in amultilayer substrate, some conductive layers of the substrate may serveas power planes, and others may serve as ground planes, depending on theoperational requirement of the application. In such cases it may bedesirable for the power delivery current loop to have low inductance.For example, in the case of high speed microprocessors, the rapidswitching of transistors can cause large transient voltage drops in thepower supply voltage, if the inductance of the power delivery loop istoo high. These voltage drops can significantly degrade themicroprocessors' speed and performance.

In general, the loop inductance between conductive layers in amultilayer organic substrate depends on the thickness of the dielectriclayer formed between the two conductive layers. As the thickness of thedielectric layer increases, the loop inductance between the twoconductive layers increases. In general, the loop inductance of aconductive path is related to the cross-sectional area between powerdelivery and ground return paths. In the case of a multilayer organicsubstrates, this cross-sectional area depends on the thickness of thedielectric layer separating power and ground planes, and on the spacingbetween vias or through-vias (plated-through vias) that make connectionsbetween layers in the multilayer organic substrate. Therefore, toachieve lower loop inductance between conductive layers in a multilayerorganic substrate, the thickness of the dielectric layer formed betweenconductive traces has to be reduced.

The thickness of the dielectric layer formed on a flat multilayeredsubstrate using present fabrication techniques, such as liquid coatingand dry film laminations, is about 20 microns or higher. In contrast,the thickness of the dielectric layer formed in a through-via usingcurrent fabrication techniques, such as a double-drilling process, is inthe range of about 75 to 100 microns. Reducing the thickness of thedielectric layers lower than 20 microns if formed on a flat surface andlower than 75 microns if formed in a through-via, increases the risk ofhaving pin holes and step coverage problems in the dielectric layer. Pinholes and step coverage problems in the dielectric layer can result inshorts between the two conductive traces during operation. Pin holes aremicroscopic holes in the dielectric layer that can become filled withconductive material, resulting in shorts between power and ground planesduring operation. Step coverage is a measure of how conformal thecoating is. If step coverage is poor, extreme thinning of the dielectriccan occur at sharp edges, such as at the corners of conductive traces.Both pin holes and step coverage problems can cause low manufacturingyields and can be points of failure in the field, resulting inreliability problems.

Therefore, there is a need in some power delivery applications for animproved fabrication technique that provides a thinner dielectric layerfree from pin holes and step coverage problems to achieve lower loopinductance values between conductive layers in a multilayered organicsubstrate.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a sectional view of a dielectric layer formed in athrough-via-in-via structure according to an embodiment of the presentinvention.

FIG. 2 shows a sectional view of one embodiment of a dielectric layerformed on a portion of a substrate material.

FIG. 3 is a sectional view of an embedded capacitor formed with adielectric layer according to an embodiment of the present invention.

FIG. 4 is a flow diagram of an exemplary method of forming a dielectriclayer in a self-aligned through-via-in-via structure according to anembodiment of the present invention.

FIG. 5 is a flow diagram of an exemplary method of forming a dielectriclayer in an embedded capacitor according to an embodiment of the presentinvention.

FIG. 6 is a flow diagram of an exemplary method of forming a dielectriclayer on a substantially planar substrate material according to anembodiment of the present invention.

DETAILED DESCRIPTION

In the following detailed description of the embodiments, reference ismade to the accompanying drawings that show, by way of illustration,specific embodiments in which the invention may be practiced. Theseembodiments are described in sufficient detail to enable those skilledin the art to understand and practice them. Other embodiments may beutilized, and structural, logical, and electrical changes may be madewithout departing from the scope of the present disclosure. Moreover, itis to be understood that the various embodiments of the invention,although different, are not necessarily mutually exclusive. For example,a particular feature, structure, or characteristic described in oneembodiment may be included within other embodiments. The followingdetailed description is, therefore, not to be taken in a limiting sense,and the scope of embodiments of the present invention are defined onlyby the appended claims, along with the full scope of equivalents towhich such claims are entitled.

The terms “coatings” and “layers” are often used interchangeably.Embodiments of the present invention are covered by both of the aboveterms as they are generally understood in the field. The terms“conductive via” and “micro via” both refer to structures for electricalconnection of conductors at different interconnect levels of amulti-level substrate. These terms are sometimes used in the art todescribe both an opening in an insulator in which the via structure willbe completed, and the completed via structure itself. For purposes ofthis disclosures, via refers to the completed structure.

The present invention, in at least one embodiment, provides a thin,conformal, and high-integrity organic dielectric layer betweenconductive layers of a multilayered substrate material that is free frompin holes and step coverage problems to reduce loop inductance betweenthe conductive layers. This is accomplished, in this embodiment, byusing an electrocoating process to form the organic dielectric layerover the substrate material.

Overview of Electrocoating

Electrocoating is a method of organic finishing that uses an electriccurrent field to deposit organic material onto a substrate material. Theprocess works on the principle of “Opposites Attract.” The fundamentalphysical principle of electrocoating is that materials with oppositeelectrical charges attract. An electrocoat system applies adirect-current (DC) charge to a substrate immersed in a bath ofoppositely-charged organic dielectric particles. The organic dielectricparticles drawn to the substrate are deposited onto the substrate,forming an even, continuous film over every surface, in every creviceand corner, until the organic dielectric coating reaches the desiredthickness. This process leaves an organic dielectric layer that is freefrom pin holes and step coverage problems. Depending on the polarity ofthe charge, electrocoating is classified as either anodic or cathodic.In anodic electrocoating, the substrate material to be electrocoated isgiven a positive charge, and in cathodic electrocoating, the substratematerial to be electrocoated is given a negative charge. In general,electrocoating offers the ability to coat complex surfaces evenly andfree of pin holes and step coverage problems. The electrocoating processcan be easily automated to increase throughput capacity. Theelectrocoating process requires low energy and minimal maintenance.Also, the electrocoating process can be controlled by voltageadjustments. Once the substrate is deposited with the dielectricmaterials, the deposition stops. The electrocoating process can becontrolled to form coatings that are less than 30 microns. Also, theprocess yields a thin, conformal, high-integrity layer that is free frompin holes and step coverage problems, because the process has theability to coat complex surfaces evenly. Currently, electrocoating iswidely used in a variety of industrial market segments.

FIG. 1 shows a sectional view of one embodiment of a through-via-in-viastructure 100 formed using a dielectric layer 110 in a substratematerial 120 according to the teachings of the present disclosure.Through-vias, also known as plated-through holes, or PTHs, are vias thatprovide conduction from one side to another side of a circuit board or amultilayer organic substrate. Through-vias are generally drilled throughthe circuit board or multilayer organic substrate including materialsuch as fiber reinforced polymer. The pitch of the through-vias isgenerally limited by a wall thickness requirement of 140 microns ormore. This pitch and wall thickness limitation can result in asignificant contribution to the loop inductance of the power deliverycircuit. An alternative design, known as via-in-via, or a coaxial via,shown in FIG. 1, provides another approach for routing both power andground signals from one side of the substrate to the other. In thisdesign shown in FIG. 1, a second, smaller diameter through-via is formedin the center of a larger through-via. This provides a power supply andground return path that are much closer together than in a conventionalthrough-via design, thus lowering inductance. In a conventionalvia-in-via, power and ground plane separation is generally 75 microns ormore.

As depicted in FIG. 1, a dielectric layer 110 is formed between firstand second conductive layers 130 and 140, respectively, in thethrough-via-in-via structure 100 of the substrate material 120. Alsoshown in FIG. 1 is an unfilled portion left in the via 100 by the secondconductive layer 140, and an optional filler material 150 disposed inthe unfilled portion of the through-via 100 such that the optionalfiller material 150 overlies the second conductive material 140.

The dielectric layer 110 shown in FIG. 1 is formed using anelectrocoating process. The thickness of the dielectric layer formed inthe through-via-in-via structure 100 using the electrocoating processcan be less than about 30 microns. The dielectric layer 110 formed usingthe electrocoating process is a thin, conformal, high-integrity coatingthat is free from pin holes and aspect ratio problems to prevent bridgesand electrical shorts. In some embodiments, the dielectric layer 110reduces loop inductance between first and second conductive layers 130and 140, respectively, when they are connected to power and groundplanes.

By electrocoating the dielectric layer 110 on the first conductive layer130 in the through-via 100, the dielectric layer 110 is aligned to thefirst conductive layer 130. The second conductive layer 140 on thedielectric layer 110 is in conformal alignment with the dielectric layer110 . Thus, the electrocoating process permits a self-alignment feature,which is far more precise than any mechanical or laser drillingalignment capability. This self-alignment permits a very thin dielectriclayer 110 between the first and second conductive layers 130 and 140,respectively, in the via-in-via structure.

Loop inductance primarily depends on geometrical factors. It isgenerally the same for different dielectrics. Loop inductance can becalculated for a through-via-in-via structure by using

L=0.2U _(r) Ln(r ₂ /r ₁)

where U_(r) is the permeability and r₂ and r₁ are outer and inner radii,respectively, of a self-aligned via-in-via structure. The followingtable illustrates some examples of computed inductance (pH/via) for coaxself-aligned wires and self-aligned via-in-via cases. It can be seenfrom the following table that the loop inductance critically depends onthe difference in length between the outer and inner radii.

Outer Wire Inner Wire Dielectric Radius (r₂) in Radius (r₁) in thicknessin Inductance micrometers micrometers micrometers (pH/via) 350 100 250200.4 350 349 1 0.46 350 349.5 0.5 0.23

The registration accuracy using conventional double-drilling processes,such as mechanical or laser drilling, to form a via-in-via structure,can be generally more than 20 microns. Thus, the loop inductanceobtained in the via-in-via structures can be several orders of magnitudehigher than the coax self-aligned wires. A conventional double-drillingprocess generally includes filling a plated via with a dielectricmaterial, and subsequently removing a portion of the dielectric materialby drilling an opening through the dielectric material to form thesecond electrode. This subsequent drilling results in double-drilling ofthe via. Due to the inherent tolerances present in the mechanical orlaser drilling operations, the registration accuracy (centering accuracyof the two drilling operations in the via) is generally more than 20microns, thus limiting the minimum thickness to greater than 20 micronsplus the thickness of the dielectric material required to preventelectrical shorts. Therefore, the final thickness of the depositeddielectric layer using a conventional double-drilling process can add upto be more than 75 to 100 microns. A dielectric process described in thepresent disclosure eliminates the need for the second drilling operationby forming a thin, conformal, high-integrity dielectric layer 110 overthe first conductive layer 130 that is less than 30 microns inthickness. This leaves a portion of the through-via unfilled to form thesecond electrode. Also, the dielectric process permits more control overthe formation of the ultimate thickness of the dielectric layer 110,thus permitting a higher control over the ultimate loop inductancebetween the conductive layers in the substrate material 120.

In some embodiments, the dielectric layer 110 is formed using highdielectric constant materials made from organic polymers and/or organicpolymer mixtures such as epoxy, epoxy-acrylate, and polyimide. Theorganic polymers and/or organic polymer mixtures used in the dielectriclayer can be modified to vary material properties such as physical,mechanical, and chemical properties. For example, material propertiescan include properties such as modulus, elongation, adhesion, glasstransition temperature, etch resistance, solvent resistance, Poisson'sratio, and coefficient of thermal expansion (CTE).

The expression “high dielectric constant material,” refers to a materialhaving a dielectric constant greater than oxides of silicon. In someembodiments, the dielectric constant is in the range of about 750 to1000. The polymer dielectrics of embodiments of the present inventionmay have high dielectric constants and may comprise easily polarizablechemical species. The polymer dielectrics of embodiments of the presentinvention comprise a polymeric structure and a metal ion held within thepolymeric structure by physical and chemical bonds. The polymerdielectrics of embodiments of the present invention are a substantialimprovement over high dielectric ceramics and polymer/ceramic blends.High dielectric ceramics require a high temperature firing. The polymerdielectrics of embodiments of the present invention do not require ahigh temperature firing. Ceramic blends are limited in flexibilitybecause of the particulate-based structure. Particles limit flexibilityby limiting the thinness of the structure. The polymer dielectrics arenot particulate-based. As a consequence, lower film thicknesses are notlimited by the size of the particulate filler, and thinner layers ofdeposition may be fabricated, as compared to ceramic blend structures.The combination of using organic polymers with an electrocoating processyields a thinner layer deposition on a substrate material than what ispossible with current fabrication techniques. The organic polymers usedin embodiments of the present invention are shapable to form articlessuch as films, sheets, disks, and other flat shapes that areparticularly useful for forming dielectric layers in multilayersubstrates including a through-via-in-via structure.

The substrate material 120 can be a multilayer printed circuit boardformed from an organic substrate supporting a plurality of insulatedconductive trace layers. The first and second conductive layers 130 and140, respectively, may be deposited using conventional electroplatingprocesses such as electroless or electrolytic plating. In someembodiments, the first and second conductive layers 130 and 140,respectively, are electroplated using conductive materials such ascopper, nickel, gold, and silver. The conductive materials providesignal paths for coupling or interconnecting electrical circuitry. Theoptional filler material 150 disposed in the unfilled portion of thethrough-via 100 can be a plugging material made from a polymer orsilica-filled epoxy, as is known in the art.

FIG. 2 shows a sectional view 200 of one embodiment of a dielectriclayer 210 formed on a portion of substantially planar substrate material220. The dielectric layer 210 is formed between a first conductive layer230 and a second conductive layer 240. The dielectric layer can also beformed on non-planar surfaces such as concave, convex, or steppedsurfaces. As shown in FIG. 2, the sectional view 200 shows the firstconductive layer 230 formed on the planar substrate material 220. Thesecond conductive layer 240 is disposed across from the first conductivelayer 230, and on the dielectric layer 210. The dielectric layer 210 isformed using the electrocoating process described with reference to FIG.1. The thickness of the dielectric layer 210 formed is less than about30 microns to reduce loop inductance between the first and secondconductive layers 230 and 240, respectively, when used as power andground planes. The dielectric layer 210 formed using the electrocoatingprocess is free from pin holes and step coverage problems to preventbridging and shorting between first and second conductive layers 230 and240, respectively, when the first and second conductive layers 230 and240, respectively, are used as power and ground planes. In someembodiments, the dielectric layer 210 is formed using high dielectricorganic polymers and/or organic polymer mixtures such as epoxy,epoxy-acrylate, and polyimide.

FIG. 3 is a sectional view of one embodiment of an embedded capacitor300 having a dielectric layer 310 between a first conductive layer 320and a second conductive material 330 in a substrate material 340. Thedielectric layer 310 in the embedded capacitor 300 is formed using theelectrocoating process described in detail with reference to FIG. 1 toattain a thin, conformal, high-integrity coating to reduce loopinductance between the first conductive layer 320 and the secondconductive material 330. In some embodiments, the thickness of thedielectric layer 310 formed using the electrocoating process can be lessthan about 30 microns in thickness. In some embodiments, the firstconductive layer 320 and the second conductive material 330 can be firstand second electrodes of the embedded capacitor 300. In someembodiments, the first and second electrodes can be power and groundelectrodes.

The dielectric layer 310 of the embedded capacitor 300 is formed usinghigh dielectric constant materials such as organic polymers and/ororganic polymer mixtures. It can be envisioned that the embeddedcapacitor 300 can include multiple layers of the dielectric layer 310separated by multiple first and second electrodes to increase thecapacitance of the embedded capacitor 300. The first conductive layer320 can be formed using a conventional electroplating process. In someembodiments, the first conductive material 320 is electroplated usingconductive materials such as copper, nickel, silver, and gold asconductors that provide signal paths for coupling or interconnectingelectrical circuitry. The second conductive material 330 can be aconductive polymer or a conductive paste. The embedded capacitor 300 caninclude one or more micro vias 360 to bring the first conductive layer320 and the second conductive material 330 to the top of a protectiveouter layer 350 formed on the substrate material 340. In someembodiments, the micro vias 360 can be connected to ground and powerplanes 380 and 370, respectively. In these embodiments, the loopinductance between the ground and power planes 380 and 370,respectively, is considerably reduced by the formed dielectric layer 310using the electrocoating process described in the present disclosure.

FIG. 4 is a flow diagram illustrating generally a method 400 of forminga dielectric layer in a self-aligned through-via-in-via structure.Method 400, as shown in FIG. 4, begins with action 410 of forming afirst conductive layer on the sidewall of a through-via in an organicsubstrate material. The through-via in the substrate material can beformed using a mechanical or laser drilling process. The substratematerial can include more than one layer such as a multilayer printedcircuit board. The first conductive layer can be electroplated usingconventional processes such as electroless or electrolytic plating. Thefirst conductive layer is electroplated using conductive materials suchas copper, nickel or gold as conductors that provide signal paths forcoupling or interconnecting electrical circuitry.

The next action 420 includes forming a dielectric layer over the firstconductive layer such that the formed dielectric layer leaves a portionof the through-via unfilled. The dielectric layer is formed using theelectrocoating process described in detail with reference to FIG. 1. Insome embodiments, the thickness of the dielectric layer formed using theelectrocoating process is less than about 30 microns. The dielectriclayer formed using the electrocoating process is a thin, conformal,high-integrity layer that is free from pin holes and step coverageproblems, that prevents the formation of bridges and electrical shorts.In some embodiments, the dielectric layer is formed using highdielectric constant materials made from organic polymers and/or organicpolymer mixtures such as epoxy, epoxy-acrylate, and polyimide. Theorganic polymers and/or organic polymer mixtures used in the dielectriclayer can be modified to vary material properties such as modulus,elongation, adhesion, and glass transition temperatures.

The next action 430 can include filling the unfilled portion of thethrough-via with a second conductive material, such that theelectrocoated thin dielectric layer provides a low loop inductancebetween the first conductive layer and the second conductive materialwhen the first conductive layer and the second conductive material areused as power and ground planes. In some embodiments, the secondconductive layer is a conductive material such as a conductive polymeror a solder paste.

Action 430 can include forming a second conductive layer over the formeddielectric layer such that the formed thin dielectric layer provides alow loop inductance between the formed first and second conductivelayers when the first and second conductive layers are used as groundand power planes. Also, the formed second conductive layer can leave aportion of the through-via unfilled. The second conductive material canbe formed with conductive materials described with reference to action410.

The next action 440 can include filling the remaining portion of theplated through-via with a plugging material. The plugging material canbe a conductive or non-conductive material. In some embodiments, theplugging material is a silica-filled epoxy. The optional action 450includes grinding to remove excess build up of the filled pluggingmaterial.

FIG. 5 is a flow diagram illustrating generally a method 500 of forminga dielectric layer in an embedded capacitor. Method 500, as shown inFIG. 5, begins with action 510 of forming a first electrode on thesidewall of a through-via in an organic substrate material. Thethrough-via in the substrate material can be formed using a mechanicalor laser drilling process. The substrate material can include more thanone layer such as a multilayer printed circuit board. The firstelectrode can be electroplated using conventional processes such aselectroless or electrolytic plating. The first electrode iselectroplated using conductive materials such as copper, nickel or goldas conductors that provide signal paths for coupling or interconnectingelectrical circuitry.

The next action 520 includes electrocoating a dielectric layer over thefirst electrode layer such that a portion of the through-via is leftunfilled. The dielectric layer is formed using the electrocoatingprocess described in detail with reference to FIG. 1. In someembodiments, the thickness of the dielectric layer formed using theelectrocoating process is less than about 30 microns. The dielectriclayer formed using the electrocoating process is a thin, conformal,high-integrity layer that is free from pin holes and step coverageproblems, that prevents the formation of bridges and electrical shorts.In some embodiments, the dielectric layer is formed using highdielectric constant materials made from organic polymers and/or organicpolymer mixtures such as epoxy, epoxy-acrylate, and polyimide. Theorganic polymers and/or organic polymer mixtures used in the dielectriclayer can be modified to vary material properties such as physical,mechanical, and chemical properties. For example, the physical,mechanical, and chemical properties can include material properties suchas modulus, elongation, adhesion, glass transition temperature, etchresistance, solvent resistance, Poisson's ratio, dielectric constants,and CTE.

The next action 530 includes forming a second electrode by filling theremaining unfilled portion of the through-via with a conductivematerial, such that the formed dielectric layer provides a low loopinductance between the first and second electrodes.

Action 530 can include forming a second electrode layer over theelectrocoated dielectric layer such that the second electrode layerleaves a portion of the through-via unfilled so that third and fourthelectrodes including a second electrocoated layer can be formed in theunfilled portion of the through-via so that the capacitance of anembedded capacitor can be increased. It can be envisioned that multiplelayers of electrodes including the electrocoated dielectric layers canbe formed to increase capacitance of the embedded capacitor. Theelectrocoating process described in the present disclosure forms a thin,conformal coating that makes it possible to have multiple layers in theembedded capacitor.

The next action 540 can include removing excess build up of the filledconductive material outside the through-via. The next action 550 caninclude forming micro vias to connect the formed first and secondelectrodes to structure outside the substrate material. The next action560 can include forming a solder mask over the formed micro vias.

FIG. 6 is a flow diagram illustrating generally a method 600 of forminga dielectric layer on a substantially planar substrate material. Method600, as shown in FIG. 6, begins with action 610 of forming a firstconductive layer on the substantially planar substrate material. Thesubstrate material can include more than one layer such as a multilayerprinted circuit board. The first conductive layer can be electroplatedusing conventional processes such as electroless or electrolyticplating. The first conductive layer is electroplated using conductivematerials such as copper, nickel, silver, and gold as conductors thatprovide signal paths for coupling or interconnecting electricalcircuitry.

The next action 620 includes electrocoating a dielectric layer over theformed first conductive layer. In some embodiments, the thickness of thedielectric layer formed using the electrocoating process is less thanabout 30 microns. The dielectric layer formed using the electrocoatingprocess is a thin, conformal, high-integrity layer that is free from pinholes and step coverage problems, and that prevents the formation ofbridges and electrical shorts. In some embodiments, the dielectric layeris formed using high dielectric constant materials made from organicpolymers and/or organic polymer mixtures such as epoxy, epoxy-acrylate,and polyimide. The organic polymers and/or organic polymer mixtures usedin the dielectric layer can be modified to vary material properties suchas modulus, elongation, adhesion, and glass transition temperatures.

The next action 630 includes forming a second conductive layer over theelectrocoated dielectric layer, such that the dielectric layer providesa low loop inductance between the first and second conductive layerswhen used as ground and power planes. The second conductive layer can beformed using similar materials used in forming the first conductivelayer described with reference to action 610. The next action 640 caninclude forming a solder mask over the formed second conductive layer.

The above-described method and apparatus provide, among other things, athin, conformal, and high-integrity organic dielectric layer betweenconductive layers of a multilayered substrate material that is free frompin holes and step coverage problems, to reduce loop inductance betweenthe conductive layers in a multilayered organic substrate to improveshielding and signal integrity.

It is to be understood that the above description is intended to beillustrative, and not restrictive. Many other embodiments will beapparent to those of skill in the art upon reviewing the abovedescription. The scope of embodiments of the invention should,therefore, be determined with reference to the appended claims, alongwith the full scope of equivalents to which such claims are entitled.

What is claimed:
 1. A capacitor, comprising: a through via having thesidewall defined by an organic substrate; a first electrode layeroverlying the sidewall of the through via; an organic dielectric layerhaving a thickness of less than about 30 microns overlie the firstelectrode leaving a portion of the through via unfilled; and a secondelectrode layer formed in the remaining unfilled portion of the throughvia.
 2. The capacitor of claim 1, wherein the organic substratecomprises more than one layer.
 3. The capacitor of claim 1, wherein theorganic dielectric layer is formed using an electrocoating process, andthe formed dielectric layer using the electrocoating process is freefrom pin holes and step coverage problems to prevent bridges orelectrical shorts between the first and second conductive layers.
 4. Thecapacitor of claim 3, wherein the organic dielectric layer is formedfrom materials selected from the group consisting of organic polymers,and organic polymer mixtures having a high dielectric constant such asepoxy, epoxy-acrylate, and polyimide.
 5. The capacitor of claim 1,further comprising: forming microvias to route the first and secondelectrode layers to a top layer on the substrate material; and forming asolder mask over the microvias such that the microvias can be connectedto power and ground planes.
 6. A capacitor, comprising: a substrate ahole through the substrate plated with a first conductive material; adielectric layer formed over the first conductive material in thethrough hole and defining a further through hole coaxially aligned withthe through hole; the dielectric layer comprising high dielectricconstant material; and a conductor formed of a second conductivematerial in the further through hole.
 7. The capacitor of claim 6,wherein a conductive layer of the first conductive material is formedover the dielectric layer and defines a still further through hole inwhich the second conductive material forms the conductor.
 8. Thecapacitor of claim 6, wherein the high dielectric content material ofthe dielectric layer is readily polarizable.
 9. The capacitor of claim6, wherein the high dielectric constant material comprises organicmaterials selected from the group consisting of organic polymers,polymer mixtures, epoxies, epoxy acrylates, and polyimides.
 10. Thecapacitor of claim 6, wherein the high dielectric content material ofthe dielectric layer is non-particulate based.
 11. The capacitor ofclaim 8, wherein the second conductive material comprises a silicafilled epoxy.
 12. The capacitor of claim 6 wherein the first and secondconductive material are not the same.
 13. The capacitor of claim 6,wherein the dielectric layer has a thickness in the hole equal to orless than about 30 microns.
 14. The capacitor of claim 7, wherein thefirst conductive material comprises an electrically conductive materialselected from the group consisting of copper, nickel, gold, and silver.15. A capacitor, comprising: a substrate a hole through the substrateplated with a conductive material; a dielectric layer formed over thefirst conductive material in the through hole and defining a smallerthrough hole; the dielectric layer comprising non-particulate, readilypolarizable, high dielectric constant material; selected from the groupconsisting of organic polymers, polymer mixtures, epoxy acrylates andpolyimides; and a conductor formed of a conductive silica filled epoxyor polymer.
 16. The capacitor of claim 15, wherein the conductor isselected from the group consisting of copper, nickel, gold and silver.